Saved in:
Bibliographic Details
Main Authors: Zhang, Bowen, Huang, Zhichao, Dai, Genan, Xu, Guangning, Fan, Xiaomao, Huang, Hu
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2407.01886
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866909238593323008
author Zhang, Bowen
Huang, Zhichao
Dai, Genan
Xu, Guangning
Fan, Xiaomao
Huang, Hu
author_facet Zhang, Bowen
Huang, Zhichao
Dai, Genan
Xu, Guangning
Fan, Xiaomao
Huang, Hu
contents Graph classification is a pivotal challenge in machine learning, especially within the realm of graph-based data, given its importance in numerous real-world applications such as social network analysis, recommendation systems, and bioinformatics. Despite its significance, graph classification faces several hurdles, including adapting to diverse prediction tasks, training across multiple target domains, and handling small-sample prediction scenarios. Current methods often tackle these challenges individually, leading to fragmented solutions that lack a holistic approach to the overarching problem. In this paper, we propose an algorithm aimed at addressing the aforementioned challenges. By incorporating insights from various types of tasks, our method aims to enhance adaptability, scalability, and generalizability in graph classification. Motivated by the recognition that the underlying subgraph plays a crucial role in GNN prediction, while the remainder is task-irrelevant, we introduce the Core Knowledge Learning (\method{}) framework for graph adaptation and scalability learning. \method{} comprises several key modules, including the core subgraph knowledge submodule, graph domain adaptation module, and few-shot learning module for downstream tasks. Each module is tailored to tackle specific challenges in graph classification, such as domain shift, label inconsistencies, and data scarcity. By learning the core subgraph of the entire graph, we focus on the most pertinent features for task relevance. Consequently, our method offers benefits such as improved model performance, increased domain adaptability, and enhanced robustness to domain variations. Experimental results demonstrate significant performance enhancements achieved by our method compared to state-of-the-art approaches.
format Preprint
id arxiv_https___arxiv_org_abs_2407_01886
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Core Knowledge Learning Framework for Graph Adaptation and Scalability Learning
Zhang, Bowen
Huang, Zhichao
Dai, Genan
Xu, Guangning
Fan, Xiaomao
Huang, Hu
Machine Learning
Artificial Intelligence
Graph classification is a pivotal challenge in machine learning, especially within the realm of graph-based data, given its importance in numerous real-world applications such as social network analysis, recommendation systems, and bioinformatics. Despite its significance, graph classification faces several hurdles, including adapting to diverse prediction tasks, training across multiple target domains, and handling small-sample prediction scenarios. Current methods often tackle these challenges individually, leading to fragmented solutions that lack a holistic approach to the overarching problem. In this paper, we propose an algorithm aimed at addressing the aforementioned challenges. By incorporating insights from various types of tasks, our method aims to enhance adaptability, scalability, and generalizability in graph classification. Motivated by the recognition that the underlying subgraph plays a crucial role in GNN prediction, while the remainder is task-irrelevant, we introduce the Core Knowledge Learning (\method{}) framework for graph adaptation and scalability learning. \method{} comprises several key modules, including the core subgraph knowledge submodule, graph domain adaptation module, and few-shot learning module for downstream tasks. Each module is tailored to tackle specific challenges in graph classification, such as domain shift, label inconsistencies, and data scarcity. By learning the core subgraph of the entire graph, we focus on the most pertinent features for task relevance. Consequently, our method offers benefits such as improved model performance, increased domain adaptability, and enhanced robustness to domain variations. Experimental results demonstrate significant performance enhancements achieved by our method compared to state-of-the-art approaches.
title Core Knowledge Learning Framework for Graph Adaptation and Scalability Learning
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2407.01886